物理化学学报 >> 2023, Vol. 39 >> Issue (2): 2205050.doi: 10.3866/PKU.WHXB202205050

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镁离子电池正极材料研究进展

张默淳1, 冯硕1, 邬赟羚1,*(), 李彦光1,2,*   

  1. 1 苏州大学功能纳米与软物质研究院, 江苏 苏州 215123
    2 澳门科技大学材料科学与工程研究院, 澳门 氹仔岛 999078
  • 收稿日期:2022-05-23 录用日期:2022-06-24 发布日期:2022-06-29
  • 通讯作者: 邬赟羚,李彦光 E-mail:ylwu@suda.edu.cn
  • 作者简介:第一联系人:

    These authors contributed equally to this work.

  • 基金资助:
    国家自然科学基金(U2002213);国家自然科学基金(51972219);国家自然科学基金(22005209)

Cathode Materials for Rechargeable Magnesium-Ion Batteries: A Review

Mochun Zhang1, Shuo Feng1, Yunling Wu1,*(), Yanguang Li1,2,*   

  1. 1 Institute of Functional Nano & Soft Materials (FUNSOM), Soochow University, Suzhou 215123, Jiangsu Province, China
    2 Macao Institute of Materials Science and Engineering, Macau University of Science and Technology, Taipa 999078, Macau SAR, China
  • Received:2022-05-23 Accepted:2022-06-24 Published:2022-06-29
  • Contact: Yunling Wu,Yanguang Li E-mail:ylwu@suda.edu.cn
  • About author:Email: yanguang@suda.edu.cn (Y.L.)
    Email: ylwu@suda.edu.cn (Y.W.)
  • Supported by:
    the National Natural Science Foundation of China(U2002213);the National Natural Science Foundation of China(51972219);the National Natural Science Foundation of China(22005209)

摘要:

镁离子电池(MIBs)因镁资源储量丰富、体积能量密度大、金属镁空气中相对稳定等优势,被认为是具有大规模储能应用潜力的电池体系。然而,镁离子较高的电荷密度和较强的溶剂化作用导致其在正极材料中的可逆脱嵌和固-液界面上的离子扩散相当缓慢,严重影响了MIBs的电化学性能。近年来,人们针对MIBs正极材料开展了大量工作,取得了一定进展,但是还存在不少问题。本文先从MIBs体系的特点出发,阐述其优势和目前所面临的主要挑战,然后从无机正极材料和有机正极材料两方面展开,梳理并总结了各类正极材料的局限性及其解决策略,对优化方法和材料性能间的相关性进行归纳和讨论,为今后进一步发展具有优异电化学性能的MIBs正极材料提供可能的参考。

关键词: 镁离子电池, 嵌入型正极, 转化型正极, 有机正极

Abstract:

Using renewable energy sources such as wind, solar, and tidal power is one of the most effective ways to address the global energy crisis and the ensuing environmental issues. As essential complementary components to renewable energy, high-performance energy storage devices and systems are urgently required. Since the 1990s, the global battery market has been dominated by lithium-ion batteries (LIBs) owing to their high energy density and long cycle life. They have been widely used in portable electronics, and more recently, in electric vehicles. However, lithium resources are limited and unevenly distributed; therefore, the manufacturing costs of LIBs are still high. There is also increasing concern about their operational safety. Thus, it is crucial to develop next-generation battery technologies with lower costs and higher safety. In recent years, magnesium-ion batteries (MIBs) have attracted increasing attention as one of the most promising multivalent ion batteries. The use of magnesium is encouraged owing to its good air stability, lower reduction potential (−2.356 V vs. standard hydrogen electrode), higher volumetric specific capacity (3833 mAh∙cm−3), and dendrite-free deposition upon cycling. Moreover, magnesium reserves (2.3%) are 1045 times more than those of lithium (0.0022%), because of which, MIBs are considerably less expensive than LIBs. The development of MIBs has, however, encountered a few challenges arising from the comprising cathodes, electrolytes, and anodes. Mg2+ ions with smaller radii and higher charge densities have strong Coulomb interactions with electrode materials, which leads to sluggish kinetics and high diffusion barriers during de-/intercalation. Contemporary electrolytes generally have poor chemical compatibility with cathodes of MIBs, narrow electrochemical windows, and high deposition overpotential, which limits the development of high-voltage MIBs. Moreover, Mg tends to react with organic solvents (especially carbonates and nitriles), forming passivation layers on the surfaces, which increase the interfacial resistance and lead to battery irreversibility. Therefore, material design and technological innovation are crucial for developing commercially viable MIBs. This review focuses on recent advances on MIB cathode materials. First, we present a brief description of the characteristics of MIBs and discuss their strengths and drawbacks. Then, we overview three types of cathode materials, namely, intercalation-type cathodes, conversion-type cathodes, and organic cathodes, followed by a summary of their limitations and recent efforts for addressing the above-mentioned challenges. We conclude with perspectives for future research directions.

Key words: Magnesium-ion battery, Intercalation-type cathode, Conversion-type cathode, Organic cathode